DE102018120965A1 - capacitor - Google Patents

Abstract

The present invention relates to a capacitor, particularly to a capacitor in which a configuration and an assembly are simplified by forming a condensation region in which plates are stacked and refrigerant is condensed, and a subcooling region in which the refrigerant is subcooled , a connecting plate is arranged, with which a gas-liquid separator is coupled between the condensation region and the subcooling region, and the refrigerant and cooling water are formed to flow between the condensation region and the subcooling region in a water-cooled condenser.

Description

TECHNICAL AREA

The present invention relates to a condenser, and more particularly, to a condenser in which a configuration and an assembly are simplified by forming a condensing region in which plates are stacked and refrigerant is condensed, and a subcooling region in which the refrigerant is subcooled Arranging a connection plate to which a gas-liquid separator is coupled between the condensation region and the sub-cooling region, and forming the refrigerant and cooling water to flow between the condensation region and the sub-cooling region into a water-cooled condenser.

BACKGROUND

In general, in a refrigeration cycle of a vehicle air conditioner, an actual cooling effect is generated by an evaporator in which heat exchange medium in a liquid state absorbs vaporization heat at the periphery and is evaporated.

A gaseous state heat exchange medium flowing from the evaporator into a compressor is compressed at high temperature and high pressure in the compressor, and liquefied heat is released to the periphery in the liquefaction process while the compressed gaseous heat exchange medium passes through the liquefier and the liquefied heat exchange medium again passing through an expansion valve and assuming a humidified low temperature, low pressure steam state and then flowing back into the evaporator to be vaporized to form a cycle.

That is, the condenser may be formed in an air-cooled type using air and a water-cooled type using liquid as the heat exchange medium for cooling the refrigerant in which gaseous high-temperature and high-pressure refrigerant flows into the condenser and condenses into the liquid state is discharged while the liquefied heat is released by heat exchange.

1 is a diagram showing a water-cooled condenser 10 in the prior art, in which a plate heat exchanger can be used, in which a plurality of plates 20 are stacked.

The water-cooled condenser 10 in the prior art is formed to a first flow unit 21 and a second flow unit 22 to contain in the a variety of plates 20 are stacked, and a first heat exchange medium flow and a second heat exchange medium flow, a first inlet pipe 31 and a first outlet pipe 32 into which the first heat exchange medium is introduced or discharged, a second inlet pipe 41 and a second outlet pipe 42 into which the second heat exchange medium is introduced or discharged, a gas-liquid separator 50 which separates the first heat exchange medium into a gaseous heat exchange medium and a liquid heat exchange medium, and a first connection pipe 51 comprising a condensation region of the first flow unit 21 and gas-liquid separator 50 connects, and a second connecting pipe 52 comprising the gas-liquid separator and a subcooling region of the first flow unit 21 combines.

In the water-cooled condenser 10 the first heat exchange medium flows through the first inlet pipe 31 is introduced into the condensation region of the first flow unit 21 , moves through the first connecting pipe 51 to the gas-liquid separator 50 , flows through the second connecting pipe 52 again in the subcooling of the first flow unit 21 and gets through the first outlet pipe 32 derived.

In this case, the second heat exchange medium becomes through the second intake pipe 41 introduced and flows into the second flow unit 22 alternating to the first flow unit 21 is formed, and cools the first heat exchange medium.

In this case, the water-cooled condenser 10 the first connecting pipe 51 which introduces the refrigerant into the gas-liquid separator and separates the introduced refrigerant into gas and liquid, and the second connection pipe 52 , which discharges the gas separated from gas and liquid refrigerant, and a configuration of the water-cooled condenser 10 is made more difficult, and the assembling efficiency of the capacitor for the complicated configuration deteriorates.

[Document of the Prior Art]

[Patent Document]

Korean Patent Published Publication No. 2012-0061534

SUMMARY

An exemplary embodiment of the present invention aims to provide a capacitor in which a configuration and arrangement are simplified by forming a condensing region in which plates are stacked and refrigerant is condensed, and a subcooling region in which the refrigerant is subcooled , a connection plate is arranged, with which a gas-liquid separator is coupled between the condensation region and the subcooling region, and the refrigerant and cooling water are formed to flow between the condensation region and the subcooling region into a water-cooled condenser.

A condenser according to the present invention includes: a condensing section in which refrigerant is condensed using cooling water; a subcooling section that subcirculates the refrigerant condensed using the cooling water; a connection plate disposed longitudinally between the condensation region and the subcooling region and formed so that the condensation region and the supercooling region can communicate with each other; and a gas-liquid separator provided on one side of a width direction in communication with the connection plate, and gas-liquid separation of the cooling water introduced from the condensation portion and discharge of the refrigerant separated into gas and liquid into the subcooling area.

Further, in the condensing region, a plurality of first plates and second plates may be alternately stacked in the longitudinal direction, and thus a cooling water flow unit in which the cooling water flows and a refrigerant flow unit in which the refrigerant flows may alternately be formed, and in the subcooling region, the plurality of first plates and second plates may be stacked alternately in the longitudinal direction, and thus the cooling water flow unit in which the cooling water flows and the refrigerant flow unit in which the refrigerant flows may alternately be formed.

In addition, the connection plate may include a first connection plate, and the first connection plate may include a connection plate body that is formed to be coupled to the first plate or the second plate between the condensation region and the supercooling region, a cooling water communication channel formed to be hollow in the connection plate body for communicating the cooling water flow units of the condensation region and the sub-cooling flow unit with each other, and a refrigerant flow channel including a refrigerant inlet channel formed in the connection plate body and the refrigerant flow unit of the condensation region and the gas-liquid separator communicate, and a refrigerant outlet channel, which allows the gas-liquid separator and the refrigerant flow unit of the subcooling, with each other to communicate.

Further, the condensing portion may include a first condensing portion and a second condensing portion divided longitudinally, and the first condensing portion and the second condensing portion may be connected to each other, and a running direction of a fluid in the first condensing portion may be opposite to the running direction of the fluid in the second condensing portion ,

In addition, the connection plate may include a second connection plate which is hollow and formed inside to fix side surfaces of the condensation region and the subcooling region, and a pipe connecting the condensation region, the gas-liquid separator and the supercooling region, and in which the cooling water and water the refrigerant flow.

Moreover, the first plate and the second plate may include a refrigerant inlet / outlet port and a refrigerant flow port that are hollow for the refrigerant to flow into communication between the refrigerant flow units formed alternately in the stacking direction and a cooling water inlet / outlet port and a cooling water flow opening that are hollow so that the cooling water is in communication with the cooling water flow units formed alternately in the stacking direction.

Further, the refrigerant inlet / outlet port may include a first protrusion projecting toward the cooling water flow unit formed at a periphery thereof, the refrigerant flow port may have a second protrusion projecting toward the cooling water flow unit formed at the periphery thereof The cooling water inlet / outlet port may include a third protrusion projecting toward the refrigerant flow unit formed at the periphery thereof, and the cooling water flow port may include a fourth protrusion protruding toward the refrigerant flow unit formed at the periphery thereof.

In addition, the gas-liquid separator may include a refrigerant inlet unit into which the refrigerant flowing through the condensation region Refrigerant is introduced, and a refrigerant outlet unit that discharges the gas and liquid separated refrigerant into the subcooling.

Further, the condensing portion may further include a first partition plate formed in the middle of the longitudinal direction and dividing the condensing portion into the first condensing portion and the second condensing portion and having a first connector having the refrigerant flow units of the first condensing portion and the second condensing portion on one side Height direction connects.

In addition, the condensation region may further include a second separation plate that divides the first condensation region or the second condensation region.

Furthermore, a length of the first condensation region may be greater than that of the second condensation region.

In addition, the gas-liquid separator may include a refrigerant inlet unit into which the refrigerant flowing through the second condensation region is introduced, and a refrigerant outlet unit that discharges the gas separated from the gas and liquid into the sub-cooling region.

Further, a part where the refrigerant is discharged from the second condensing portion and an inlet of the refrigerant inlet unit may be formed at the same height with each other.

Further, the second connection plate may include a connection plate body having an inner hollow shape and formed to be connected to the first plate or the second plate between the condensation region and the sub-cooling region, a cooling water connection pipe provided in the connection plate body and connecting the cooling water flow unit and a refrigerant connection pipe provided in the connection plate body and connecting the refrigerant flow unit and the gas-liquid separator.

In addition, the refrigerant connection piping may include a refrigerant flow piping connected to the refrigerant flow unit and a connection piping formed to be connected to the side surface of the refrigerant flow piping and formed to be connected to the gas-liquid separator.

Further, the second connection plate may include each of the connection plate body, the cooling water connection pipe, the coolant connection pipe, and the connection pipe formed to be connected to each other.

In addition, the refrigerant flow piping may have a closed shape in the longitudinal direction and a refrigerant flow tube opening formed to penetrate to couple the side surface of the refrigerant flow piping to the connection piping.

Further, the first connection plate may further include a first gas-liquid separator coupling portion having an open shape to cover a part of the gas-liquid separator and be coupled to the gas-liquid separator disposed on one side in the width direction , and a first additional fixing unit formed on the other side in the width direction and formed to be coupled to the side surface of the first plate or the second plate.

Further, the second connection plate may further include a second gas-liquid separator coupling portion having an open shape to cover a part of the gas-liquid separator and coupled to the gas-liquid separator on one side in the width direction and a second additional fixing unit formed on the other side in the width direction and formed to be coupled to the side surface of the first plate or the second plate.

In addition, the condenser may also include a mounting unit that secures the condensation area and the subcooling area that are selected.

list of figures

• 1 FIG. 14 is a diagram illustrating a prior art capacitor. FIG.
• 2 FIG. 15 is a diagram illustrating a perspective view of a capacitor according to a first exemplary embodiment of the present invention. FIG.
• 3 FIG. 10 is a diagram illustrating an exploded perspective view of the capacitor according to the first exemplary embodiment of the present invention. FIG.
• 4 FIG. 15 is a diagram illustrating that a first plate is stacked in the capacitor according to the first exemplary embodiment of the present invention.
• 5 FIG. 15 is a diagram illustrating that a second plate is stacked in the capacitor according to the first exemplary embodiment of the present invention.
• 6 FIG. 15 is a diagram illustrating a connection plate and a gas-liquid separator of the condenser according to the first exemplary embodiment of the preset invention. FIG.
• 7 FIG. 14 is another diagram illustrating a perspective view of the capacitor according to the first exemplary embodiment of the present invention. FIG.
• 8th FIG. 10 is a diagram illustrating a perspective view of a capacitor according to a second exemplary embodiment of the present invention. FIG.
• 9 FIG. 15 is a diagram illustrating a state in which a part of the capacitor according to the second exemplary embodiment of the present invention is cut. FIG.
• 10 FIG. 15 is a diagram illustrating a cross-sectional view of the capacitor according to the second exemplary embodiment of the present invention. FIG.
• 11 FIG. 15 is a diagram illustrating an exploded perspective view of a capacitor according to a third exemplary embodiment of the present invention. FIG.
• 12 FIG. 15 is a diagram illustrating a plan view of the capacitor according to the third exemplary embodiment of the present invention. FIG.
• 13 FIG. 15 is a diagram illustrating a connection plate of the capacitor according to the third exemplary embodiment of the present invention. FIG.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, a capacitor according to the invention described above will be described in detail with reference to the accompanying drawings.

<First exemplary embodiment>

2 FIG. 12 is a diagram illustrating a perspective view of a capacitor according to a first exemplary embodiment of the present invention, and FIG 3 FIG. 10 is a diagram illustrating an exploded perspective view of the capacitor according to the first exemplary embodiment of the present invention. FIG.

With reference to the 2 to 3 , includes the capacitor 1000 according to the first exemplary embodiment of the present invention generally a condensation region 200 in which refrigerant is condensed, a subcooling area 300 in which the refrigerant is subcooled, a connecting plate 400 which is connected to allow the condensation area 200 and the subcooler area 300 communicate with each other and a gas-liquid separator positioned in the connection plate 500 ,

In the condensation area 200 is a variety of first plates 110 and second plates 120 alternately stacked in a longitudinal direction and thus can a cooling water flow unit 130 in which cooling water flows, and a refrigerant flow unit 140 in which the refrigerant flows alternately in a space between the first plate 110 and the second plate 120 be formed, and the refrigerant is preferably introduced and the refrigerant is condensed.

In the subcooling area 300 is the variety of the first plates 110 and second plates 120 alternately stacked in the longitudinal direction, and thus the cooling water flow unit 130 in which the cooling water flows, and the refrigerant flow unit 140 in which the refrigerant flows alternately in the space between the first plate 110 and the second plate 120 be formed, and the cooling water is preferably introduced and the refrigerant is undercooled.

The connection plate 400 is between the condensation area 200 and the subcooling area 300 arranged in the longitudinal direction and formed to allow the condensation region 200 and the subcooler area 300 communicate with each other, the cooling water and the refrigerant in the condensation region 200 and the subcooling area 300 can communicate with each other.

The gas-liquid separator 500 is in one side of a width direction in communication with the connection plate 400 and includes a refrigerant inlet unit into which the refrigerant flows and in the condensation region 200 is condensed, and a refrigerant outlet unit, the separated gas and liquid refrigerant in the subcooling 300 omits.

That is, in the condenser 1000 According to an exemplary embodiment of the present invention, the refrigerant is preferably in the condensation area 200 introduced and heat exchanged with the cooling water, whereby the refrigerant condenses, and the condensed refrigerant is passed through the gas-liquid separator 500 separated gas and liquid and then flows into the subcooling 300 and is heat exchanged with the cooling water, preferably in the subcooling area 300 is introduced, whereby the refrigerant is undercooled.

In contrast to the refrigerant, the cooling water is preferably in the subcooling 300 is introduced, is heat exchanged with the refrigerant and flows into the condensation zone, passing through the connection plate 400 runs, and is then left out.

In this case, the cooling water is preferably supplied and flows into the subcooling region 300 , and as a result, there is an advantage in that the efficiency of a vehicle air conditioner is increased.

Further, the connection plate 400 between the condensation area 200 and the subcooling area 300 arranged in which the first plate 110 and the second plate 120 stacked and with the first plate 110 or the second plate 120 coupled, and as a result, the end plate in which the first plate 110 and the second plate 120 stacked, not be provided separately, which is advantageous in that a weight is reduced.

The capacitor 1000 according to the first exemplary embodiment of the present invention will be described in more detail.

4 FIG. 15 is a diagram illustrating that a first plate is stacked in the capacitor according to the first exemplary embodiment of the present invention, and FIG 5 FIG. 15 is a diagram illustrating that a second plate according to the first exemplary embodiment of the present invention is stacked in the capacitor. FIG.

With reference to the 4 and 5 are the first plate and the second plate 120 formed to a refrigerant inlet / outlet opening 151 and a refrigerant flow opening 152 which are hollow, so that the refrigerant in communication between the refrigerant flow units 140 flows, which are alternately formed in the stacking direction, and a cooling water inlet / outlet port 153 and a cooling water flow opening 154 that are hollow so that the cooling water in communication with the cooling water flow unit 130 is, which is formed alternately in the stacking direction.

In this case, the refrigerant inlet / outlet ports are 151 , the refrigerant flow opening 152 , the cooling water inlet / outlet opening 153 and the cooling water flow opening 154 preferably formed so that it reaches each corner of the first plate 110 and the second plate 120 adjoin.

The refrigerant inlet / outlet port 151 is hollow so that the refrigerant in communication between the refrigerant flow units 140 flows, which are alternately formed in the stacking direction, and a first projection 161 which is the cooling water flow unit 130 protrudes, is at the periphery of the refrigerant inlet / outlet port 151 educated.

The refrigerant flow opening 152 is hollow, so that the refrigerant in communication between the alternately formed in the stacking direction refrigerant flow units 140 flows, and a second projection 162 which is the cooling water flow unit 130 protrudes, is at the periphery of the refrigerant flow opening 152 educated.

The cooling water inlet / outlet opening 153 stands out and is hollow, so that the cooling water between the cooling water flow units formed alternately in the stacking direction 130 flows, and a third projection 163 leading to the refrigerant flow unit 140 protrudes, is on the circumference of the cooling water inlet / outlet opening 153 educated.

The cooling water flow opening 154 is hollow, so that the cooling water between the cooling water flow units formed alternately in the stacking direction 130 flows, and a fourth projection 164 , which is the refrigerant flow unit 140 protrudes, is at the periphery of Kühlwasserströmungsöffhung 154 educated.

In this case, in the capacitor 1000 According to an exemplary embodiment of the present invention, a refrigerant inlet, through which the refrigerant is introduced, and a refrigerant outlet, through which the refrigerant is discharged, at the refrigerant inlet / outlet port 151 be formed, which is arranged in the longitudinal direction on an outermost surface.

In addition, at the cooling water inlet / outlet opening 153 formed longitudinally at the outermost surface, a cooling water inlet through which the cooling water is introduced, and a cooling water outlet through which the cooling water is discharged are formed.

Of course, the condenser has 1000 According to the first exemplary embodiment of the present invention, preferably, a refrigerant inlet and a refrigerant outlet, so that the refrigerant is preferably in the condensation region 200 introduced and through the subcooling area 300 is discharged, and preferably has a cooling water inlet and a cooling water outlet, so that the cooling water is preferably in the subcooling 300 initiated and through the condensation area 200 is omitted.

With reference to the 3 and 6 can the connection plate 400 of the capacitor 1000 According to the first exemplary embodiment of the present invention be configured to a first connection plate 400a to contain, and the first connection plate 400a may be configured to a connection plate body 410a , a cooling water connection channel 429a and a refrigerant flow passage 430a to contain.

The connection plate body 410a is between the condensation area 200 and the subcooling area 300 arranged and is formed to with the first plate 110 or the second plate 120 that are in the condensation area 200 and the subcooling area 300 are stacked, coupled, and is with the first plate 110 and the second plate 120 coupled around the condensation area 200 and the subcooling area 300 to separate from each other, and when the Verbindungsplattenkörper 410a Having a form in which the coupling is simple, various forms of exemplary embodiments are available.

The cooling water connection channel 420a is in the connection plate body 410a formed and hollow, that the cooling water flow units 130 the condensation area 200 and the subcooling area 300 communicate with each other.

More specific is the cooling water connection channel 420a in the connection plate body 410a formed and hollow, so that the cooling water flow openings 154 the condensation area 200 and the subcooling area 300 communicate with each other.

The cooling water connection channel 420a must be formed so that it communicates with the cooling water flow opening 154 coupled and hollow, so that the cooling water of the condensation area 200 and the subcooling area 300 can flow.

In this case, the capacitor can 1000 According to the first exemplary embodiment of the present invention be formed in such a way that, because the cooling water is preferably the overcooling region 300 is fed into the overcooling area 300 introduced cooling water through the cooling water connection channel 420a the connection plate 400 in the condensation area 200 flows and then is omitted.

The refrigerant flow channel 430a is formed, so that the refrigerant flow unit 140 the condensation area 200 and the refrigerant flow units 140 of the gas-liquid separator 500 and the super cooling area 300 communicate with each other and, and he is generally formed, so he has a refrigerant inlet duct 431a and a refrigerant outlet passage 432a includes.

The refrigerant inlet channel 431a is inside the terminal plate body 410a is formed and formed around the refrigerant inlet portion 140 the condensation area 200 and the refrigerant inlet unit of the gas-liquid separator 500 to communicate, and the refrigerant inlet channel 431a is in communication with the refrigerant flow unit 140 the condensation area 200 in the longitudinal direction, and because of the gas-liquid separator 500 on one side of the width direction of the connection plate 400 is provided, the gas-liquid separator 500 in the connection plate body 410a bent to communicate with the refrigerant inlet unit of the gas-liquid separator 500 to stand.

In particular, the refrigerant inlet channel 431a inside the connection plate body 410a is formed and formed around the refrigerant flow opening 152 the condensation area 200 and the refrigerant inlet unit of the gas-liquid separator 500 to communicate, and the refrigerant inlet channel 431a is in communication with the refrigerant flow port 152 the condensation area 200 in the longitudinal direction, and because of the gas-liquid separator 500 on one side of the width direction of the first connection plate 400a is provided, the gas-liquid separator 500 in the first connection plate body 410a bent to communicate with the refrigerant inlet unit of the gas-liquid separator 500 to stand.

The refrigerant outlet channel 432a is in the connection plate body 410a is formed and is formed to communicate with the refrigerant outlet unit of the gas-liquid separator 500 and the refrigerant flow unit 140 of the subcooling area 300 in communication, and the refrigerant outlet channel 432a is bent to be in communication with the connector plate body 410a stand so that it communicates with the refrigerant outlet unit of the gas-liquid separator 500 which is on one side of the width direction of the first connection plate 400a is formed, and the refrigerant flow unit 140 of the subcooling area 300 , which is formed in the longitudinal direction, is in communication.

In particular, the refrigerant outlet channel 432a in the connection plate body 410a formed and formed with the refrigerant outlet of the gas-liquid separator 500 and the refrigerant flow opening 152 of the subcooling area 300 in communication, and the refrigerant outlet channel 432a is bent to communicate with the refrigerant outlet unit of the gas-liquid separator 500 on one side of the width direction of the first connection plate 400a and the refrigerant flow opening 152 of the subcooling region formed in the longitudinal direction is in communication.

As described above, the capacitor includes 1000 According to the first exemplary embodiment of the present invention, the condensation region 200 in which the refrigerant is preferably introduced, and the subcooling region 300 in which the cooling water is preferably introduced and flows, and includes the connection plate 400 with a first connection plate 400a that the condensation area 200 and the subcooling area 300 separates from each other, and the first connection plate 400a includes a connector plate body 410a that with the first plate 110 or the second plate 120 the condensation area 200 and the subcooling area 300 is coupled, a cooling water connection channel 420a in the connection plate body 410a is hollow to allow the cooling water in the subcooling area 300 and the condensation area 200 flows, and a refrigerant flow channel 430a in which the refrigerant is in the condensation zone 200 condenses to the gas-liquid separator 500 flows in the gas-liquid separator 500 is separated into gas and liquid, and thereafter, the refrigerant flows to the refrigerant flow port 152 of the subcooling area 300 ,

Because the end plate is not separate in the first plate 110 and the second plate 120 must be provided in the condensation area 200 and in the subcooler area 300 through the connection plate body 410a stacked, it is therefore advantageous that the weight is reduced.

Further, since the cooling water and the refrigerant flow through the first connection plate 400a , which has a simple configuration, can be brought into communication with each other or the gas-liquid separator 500 can be fed, a pipeline through which the refrigerant to the gas-liquid separator 500 flows, eliminates, and the pipe can pass through the first connection plate 400a be replaced, so that there is no risk of breakage or leakage due to external impact. In particular, the overall configuration and shape of the capacitor 1000 simplified.

In addition, the first connection plate includes 400a a first gas-liquid separator coupling section 440a with a shape in which the first gas-liquid separator coupling section 440a open to a part of the gas-liquid separator 500 to cover on one side of the width direction, and at which the gas-liquid separator 500 coupled and positioned.

As illustrated in the drawing, the first gas-liquid separator coupling section 440a a shape in which the first gas-liquid separator coupling section 440a curved and open to an outer peripheral surface of the gas-liquid separator 500 having a substantially cylindrical shape to match the gas-liquid separator 500 slightly on one side of the width direction of the first connection plate 400a to fix.

That is because in the condenser 1000 According to the first exemplary embodiment of the present invention, the gas-liquid separator 500 over the connection plate 400 including the first connection plate 400a is positioned and fixed on one side of the width direction, it is advantageous in that the gas-liquid separator 500 easy to arrange and fix, and as a result with the condenser 1000 a space in the longitudinal direction in the vehicle can be reduced.

As the first gas-liquid separator coupling section 440a the first connection plate 400a at a selected location on both sides of the gas-liquid separator 500 Positioned to be coupled width direction, the first gas-liquid separator coupling portion 440a easy in different vehicles with the condenser 1000 be arranged, whereby the first gas-liquid separator coupling section 440a is applied to different vehicles.

In addition, the first connection plate 400a Further, a first additional attachment portion 450 which projects to the other side in the width direction and extends in the longitudinal direction to a side surface of the first plate 110 or the second plate 120 the condensation area 200 and the subcooling area 300 to be coupled.

The first additional attachment section 450 is formed to match the side surfaces of the first plate 110 or the second plate 120 that in the condensation region 200 and in the subcooler area 300 Stacked are to be coupled to the connection plate 400 firmly between the condensation area 200 and the subcooling area 300 to couple and so prevent leakage of the refrigerant or cooling water.

Of course, the shape of the first additional attachment portion 450 not limited, as long as it is easy, with the first plate 110 or the second plate 120 the condensation area 200 and the subcooling area 300 Of course, various exemplary embodiments may be practiced.

With reference to 7 can the capacitor 1000 Further, according to the first exemplary embodiment of the present invention, a support unit 600 for fixing the condensation area 200 and the subcooling area 300 include that are selected.

The mounting unit 600 can the condensation area 200 and the subcooling area 300 fasten and carry and may have a form for attachment to a separate location of the vehicle, that is, various exemplary embodiments may be carried out, and as a result, the mounting unit 600 not limited.

Second Exemplary Embodiment>

8th FIG. 15 is a diagram illustrating a perspective view of a capacitor according to a second exemplary embodiment of the present invention; FIG. 9 FIG. 15 is a diagram illustrating a state in which a part of the capacitor according to the second exemplary embodiment of the present invention is cut; and FIG 10 FIG. 15 is a diagram illustrating a cross-sectional view of the capacitor according to the second exemplary embodiment of the present invention. FIG.

With reference to the 8th to 10 , includes a condensation area 200 According to a second exemplary embodiment of the present invention, a first condensation region 210 , a second condensation area 220 and a first partition plate 230 ,

In the first condensation area 210 That is, plural plates are stacked in the longitudinal direction, and the cooling water flow unit in which a cooling target fluid flows and a refrigerant flow unit in which the refrigerant flows are formed alternately.

The cooling water flowing in the cooling water flow unit may be water, air, or other fluids, and in the exemplary embodiment, it is described that the cooling target fluid is water, that is, water. H. the cooling water.

In this case, a length of the first condensation region 210 greater than that of the second condensation region 220 , That is, the first plate 110 and the second plate 120 that the first condensation area 210 and the second condensation area 220 represent, are equal to each other, and if the first plate 110 and the second plate 120 are stacked at an equal distance from each other, the sum total of the numbers of the first and second disks 110 and 120 that the first condensation area 210 form greater than the total of the numbers of the first and second disks 110 and 120 that the second condensation area 220 form.

The first partition 230 is in the longitudinal direction of the condensation region 200 formed and divides the condensation area 200 in a first condensation area 210 and a second condensation area 220 to the cooling water flow unit or to an outermost side in the longitudinal direction of the first condensation area 210 screened refrigerant flow unit.

The first partition 230 has a first connector 231 with the refrigerant flow unit of the first condensation region 210 on the other side (lower side in the drawing) in the height direction to be a passage for moving the refrigerant of the first condensation area 210 to the second condensation area 220 to serve.

That is, the refrigerant introduced through a refrigerant inlet 51 into the refrigerant flow unit within the first condensation area 210 is introduced, moves in the height direction of the first condensation region 210 down and then flows through the first connector opening 231 to the refrigerant flow unit of the second condensation region 220 ,

In this case, a flow path of the refrigerant in a U-shaped structure is configured in consideration of the refrigerant that is in the first and second condensation regions 210 and 220 condensed and changed in a certain volume, so that a flow rate of the refrigerant must not be reduced.

The refrigerant passing through the first condensation area 210 and the second condensation area 220 runs, is over the connection plate 400 in the gas-liquid separator 500 introduced and then from the gas-liquid separator 500 back to the subcooler area 300 initiated, and then via a refrigerant outlet 52 omitted.

In an exemplary embodiment of the present invention described above, the refrigerant condensed in the specific volume and changed is moved in a zigzag direction to the flow path through the first and second condensation region 210 and 220 to expand, and to thereby avoid that the flow velocity through the U-shaped structure is reduced, and if necessary, a second partition plate (not illustrated) and a third condensation area (not illustrated) having the same configuration as the first partition plate 230 and the second condensation area 220 between the second condensation area 220 and the connection plate 400 added, ie on one side of the second condensation zone 220 to expand the flow path of the refrigerant.

The first plate 110 and the second plate 120 that the first condensation area 210 and the second condensation area 220 can be arranged so that they face the same surface.

That is, the first plate 110 and the second plate 120 can be symmetrical to the first partition 230 be stacked, seen from the direction in which the first plate 110 and the second plate 120 and this is to prevent the flow velocity of the refrigerant flowing through the refrigerant flow unit of the second condensation region 220 flows through it by the refrigerant flow unit of the first condensation region 210 flows, which is configured in a zigzag direction is reduced, and for the same purpose, a section where the refrigerant from the second condensation area 220 is discharged at the same height as a refrigerant inlet passage 431 be formed, which is a section where that from the second condensation area 220 discharged refrigerant via the connection plate 400 in the gas-liquid separator 500 is initiated.

<Third exemplary embodiment>

11 FIG. 15 is a diagram illustrating an exploded perspective view of a capacitor according to a third exemplary embodiment of the present invention; FIG. 12 FIG. 15 is a diagram illustrating a plan view of the capacitor according to the third exemplary embodiment of the present invention; and FIG 13 FIG. 15 is a diagram illustrating a connection plate of the capacitor according to the third exemplary embodiment of the present invention. FIG.

With reference to the 11 to 13 , includes the connection plate 400 of the capacitor 1000 According to the third exemplary embodiment of the present invention, a second connecting plate 400b with a connection plate body 410b that is made to work with the first plate 110 or the second plate 120 between the condensation area 200 and the subcooling area 300 to be coupled.

The connection plate body 410b the second connection plate 400b may have a frame shape in which the inside is hollow, and preferably has a simple shape for minimizing the weight when the connection plate body 410b having a predetermined strength.

In addition, the second connection plate includes 400b a cooling water connection pipe 420b formed to communicate with the connector plate body 410b to be coupled, and connects the cooling water flow unit 130 ,

The cooling water connection pipe 420b has a tubular shape and is provided to communicate with the cooling water flow unit 130 to communicate, thereby allowing the cooling water to flow.

In addition, the cooling water connection pipe is 420b formed to with the connection plate body 410b to be coupled and is separate from the connection plate body 410b manufactured and assembled by soldering and using the cooling water connection pipe 420b if necessary is preferred.

That is, the cooling water connection pipe 420b does not form the flow path through which the cooling water enters the connection plate body 410b flows, but the cooling water flows through the separately formed cooling water connection pipe 420b , and as a result, an unnecessary weight increase can be prevented, and since a flow path in which the cooling water flows may not be in the connection plate body 410b is formed, a production time is shortened.

In this case, the connection plate body 410b a through hole into which the cooling water connection pipe 420b penetrates to the cooling water flow units 130 to connect with each other.

In addition, the second connection plate 400b configured to further include a refrigerant connection pipe 430b including a refrigerant flow piping 431b to be formed with the connection plate body 410b coupled to and formed with the refrigerant flow unit 140 in a selected direction, and a communication pipeline 432b that is formed to communicate with the refrigerant flow piping 431b to be coupled, and is formed to with the gas-liquid separator 500 to be coupled.

In this case, the refrigerant flow piping is 431b a cup shape with a closed shape inward in the longitudinal direction.

In addition, a selected side surface of the refrigerant flow piping is 431b configured to include a refrigerant flow line opening formed to penetrate to the connecting pipe 432b to be coupled.

That is, the refrigerant in the refrigerant flow unit 140 flows through the refrigerant flow piping 431b and the refrigerant flows to the gas-liquid separator 500 through the connecting pipe 432b connected to the refrigerant flow piping 431b in contrast, the refrigerant flowing out of the gas-liquid separator flows 500 is discharged through the connecting pipe 432b on the other side and is on the opposite side along the refrigerant flow piping 431b omitted.

The gas-liquid separator 500 is configured to include a refrigerant inlet unit formed to communicate with the connecting pipe 432b to be coupled and into which the refrigerant passing through the condensation area 200 flows, and a refrigerant outlet unit, the separated gas and liquid refrigerant through the connecting pipe 432b omits.

In the refrigerant connection pipe 430b become the refrigerant flow piping 431b and the connecting pipe 432b separately from the connection plate body 410b manufactured and as needed similar to the cooling water connection pipe 420b coupled by soldering.

That is, in the refrigerant flow piping 431b and in the connecting pipe 432b is the flow path through which the refrigerant to the gas-liquid separator 500 flows, not in the connection plate body 410b but the refrigerant flows through the refrigerant communication piping 430b including the refrigerant flow piping 431b and the connecting pipe 432b , which are manufactured separately, and as a result, the unnecessary weight increase can be avoided and because the flow path in which the refrigerant flows, not in the connection plate body 410b must be formed, the production time is shortened.

As described above, the capacitor includes 1000 According to the third exemplary embodiment of the present invention, a condensation region 200 in which the refrigerant is preferably introduced and flows, and the subcooling region 300 in which the cooling water is preferably introduced and flows, and includes a connection plate 400b that the condensation area 200 and the subcooling area 300 separates from each other, and the second connection plate 400b includes a connector plate body 410b that with the first plate 110 or the second plate 120 the condensation area 200 and the subcooling area 300 is coupled, a cooling water connection pipe 420b in which cooling water flows and which is manufactured separately and with the connection plate body 410b is coupled, and a refrigerant connection pipe 430b in which the refrigerant is in the condensation zone 200 condenses to the gas-liquid separator 500 flows and after gas and liquid is separated, and thereafter, the refrigerant flows to the refrigerant flow unit 140 of the subcooling area 300 and made separately and with the connection plate body 410b is coupled.

Because the end plate is not separate in the first plate 110 and the second plate 120 must be provided in the condensation area 200 and in the subcooler area 300 through the connection plate body 410b stacked, it is advantageous that the weight is reduced.

In addition, the second connection plate includes 400b Further, according to the third exemplary embodiment of the present invention, a second gas-liquid separator coupling portion 440b which has an open shape around a part of the gas-liquid separator 500 cover and with the gas-liquid separator 500 is coupled, which is positioned on one side in the width direction.

As illustrated in the drawing, the second gas-liquid separator coupling section 440b a shape in which the first gas-liquid separator coupling section 440b curved and open to an outer peripheral surface of the gas-liquid separator 500 with a substantially cylindrical shape to the gas-liquid separators 500 slightly on one side of the width direction of the second connection plate 400b to fix.

That is because in the condenser 1000 According to an exemplary embodiment of the present invention, the gas-liquid separator coupling section 440b over the second connection plate 400b is positioned and fixed on one side of the width direction, it is advantageous in that the gas-liquid separator 500 easy to arrange and fix, and as a result with the condenser 1000 a space in the longitudinal direction in the vehicle can be reduced.

Since the second gas-liquid separator coupling section 440b the second connection plate 400b at a selected location on both sides of the gas-liquid separator 500 Positioned to be coupled width direction, the second gas-liquid separator coupling portion 440b easy in different vehicles with the condenser 1000 be arranged, whereby the second gas-liquid separator coupling section 440b is applied to different vehicles.

In addition, the second connection plate 400b further a second additional attachment portion 450b which projects to the other side in the width direction and extends in the longitudinal direction to a side surface of the first plate 110 or the second plate 120 the condensation area 200 and the subcooling area 300 to be coupled.

The second additional attachment section 450b is formed to match the side surfaces of the first plate 110 or the second plate 120 that are in the condensation area 200 and in the subcooler area 300 Stacked are to be coupled to the second connection plate 400b firmly between the condensation area 200 and the subcooling area 300 to couple and so prevent leakage of the refrigerant or cooling water.

Of course, the shape of the second additional attachment portion 450b not limited, as long as it is easy, with the first plate 110 or the second plate 120 the condensation area 200 and the subcooling area 300 Of course, various exemplary embodiments may be practiced.

A condenser according to the present invention is advantageous in that a configuration and an assembly are simplified by forming a condensation region in which plates are stacked and refrigerant is condensed, and a subcooling region in which the refrigerant is subcooled is arranged a connection plate to which a gas-liquid separator is coupled between the condensation region and the sub-cooling region, and the refrigerant and cooling water are formed to flow between the condensation region and the sub-cooling region.

Further, the capacitor of the present invention is advantageous in that end plates of a first plate and a second plate which are stacked to form a condensation region and a subcooling region can be replaced by a connection plate.

In addition, since a piping into which refrigerant is introduced into and discharged from a gas-liquid separator is eliminated, the configuration of the condenser is simplified and the external piping damage to the piping is prevented, thereby preventing leakage of the refrigerant.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• KR 20120061534 [0010]

Claims (20)

A capacitor comprising: a condensation region in which refrigerant is condensed by using cooling water; a subcooling area that cools the refrigerant condensed by using the cooling water; a connection plate disposed and formed between the condensation region and the subcooling region in a longitudinal direction to allow the condensation region and the subcooling region to communicate with each other; and a gas-liquid separator provided on one side of a width direction in communication with the connection plate, and gas-liquid separation of the cooling water introduced from the condensation portion and discharge of the refrigerant separated into gas and liquid; into the subcooling area. Capacitor after Claim 1 wherein in the condensation region, a plurality of first plates and second plates are stacked alternately in a longitudinal direction, whereby a cooling water flow unit in which the cooling water flows and a refrigerant flow unit in which the refrigerant flows are alternately formed, and in the subcooling region, the plurality the first plates and the second plates are alternately stacked in the longitudinal direction, and thus the cooling water flow unit in which the cooling water flows and the refrigerant flow unit in which the refrigerant flows are alternately formed. Capacitor after Claim 2 wherein the connection plate includes a first connection plate, and the first connection plate includes a connection plate body formed to be connected to the first plate or the second plate between the condensation region and the subcool region, a cooling water communication channel formed, to be hollow in the connecting plate body so that the cooling water flow unit of the condensing portion and the sub-cooling unit communicate with each other, and a refrigerant flow channel including a refrigerant inlet channel formed in the connection plate body and the refrigerant flow unit of the condensation portion and the gas-liquid cutter to each other communicate, and a refrigerant outlet channel that allows the gas-liquid separator and the refrigerant flow unit of the sub-cooling region to communicate with each other. Capacitor after Claim 2 wherein the condensing portion includes a first condensing portion and a second condensing portion divided in a longitudinal direction, and wherein the first condensing portion and the second condensing portion are connected to each other and a running direction of a fluid in the first condensing portion is opposite to the running direction of the fluid in the second condensing portion is. Capacitor after Claim 2 wherein the connection plate includes a second connection plate which is hollow and formed inside to fix side surfaces of the condensation region and the supercooling region and includes a pipeline connecting the cooling region, the gas-liquid separator and the subcooling region in which the cooling water and the refrigerant flow. Capacitor after Claim 2 wherein the first plate and the second plate include a refrigerant inlet / outlet port that is hollow such that the refrigerant flows into communication between the refrigerant flow units formed alternately in a stacking direction and a cooling water inlet / outlet port and a cooling water flow opening that are hollow for the cooling water to flow in communication with the cooling water flow units that are alternately formed in a stacking direction. Capacitor after Claim 6 wherein the refrigerant inlet / outlet port has a first protrusion projecting toward the cooling water flow unit formed at a periphery thereof, the refrigerant flow opening having a second protrusion projecting toward the cooling water unit formed at a periphery thereof, the cooling water inlet The drain port has a third protrusion projecting toward the refrigerant flow unit formed at a periphery thereof, and the cooling water flow port has a fourth protrusion protruding toward the refrigerant flow unit formed at a periphery thereof. Capacitor after Claim 1 wherein the gas-liquid separator includes a refrigerant inlet unit into which the refrigerant flowing through the second condensation region is introduced, and a refrigerant drain unit that discharges the gas-liquid separated refrigerant into the super-cooling region. Capacitor after Claim 4 wherein the condensation region further includes a first partition plate formed in the middle of the longitudinal direction and separating the condensation region into the first condensation region and the second capacitor region, and having a first connector connecting the refrigerant flow units of the first condensation region and the second condensation region on a side in a height direction. Capacitor after Claim 9 wherein the condensation region further includes a second separation plate that divides the first condensation region or the second condensation region. Capacitor after Claim 4 wherein a length of the first condensation region is greater than that of the second condensation region. Capacitor after Claim 7 wherein the gas-liquid separator includes a refrigerant inlet unit into which the refrigerant flowing through the second condensation region is introduced, and a refrigerant drain unit that discharges the gas-liquid separated refrigerant into the super-cooling region. Capacitor after Claim 12 wherein a part where the refrigerant is discharged from the second condensation region and an inlet of the refrigerant inlet unit are formed at the same height to each other. Capacitor after Claim 5 wherein the second connection plate includes a connection plate body having an inner hollow shape and formed to be connected to the first plate or the second plate between the condensation region and the subcooling region, a cooling water connection pipe provided in the connection plate body and connects the cooling water flow unit, and a refrigerant connecting pipe, which is provided in the connection plate body and connects the refrigerant flow unit and the gas-liquid separator. Capacitor after Claim 14 wherein the refrigerant connection pipe includes a refrigerant flow pipe connected to the refrigerant flow unit, and a connection pipe formed to be coupled to the side surface of the refrigerant flow pipe and formed to be coupled to the gas-liquid cutter. Capacitor after Claim 15 wherein the second connection plate has each of the connection plate body, the cooling water connection pipe, the refrigerant connection pipe, and the connection pipe formed to be connected to each other. Capacitor after Claim 15 wherein the refrigerant flow piping has a closed shape inward in the longitudinal direction, and a refrigerant flow tube opening formed to penetrate to connect the side surface of the refrigerant flow piping to the connection piping. Capacitor after Claim 3 wherein the first connection plate further includes a first gas-liquid cutter coupling portion having an opened shape to cover a part of the gas-liquid cutter and connected to the gas-liquid cutter on one side is positioned in the width direction, and a first additional fixing unit formed on the other side in the width direction and formed to be coupled to the side surface of the first plate or the second plate. Capacitor after Claim 14 wherein the second connection plate further comprises a second gas-liquid cutter coupling portion having an opened shape to cover a part of the gas-liquid cutter and connected to the gas-liquid cutter and on one side in the Width direction is positioned, and a second additional fastening unit, which is formed on the other side in the width direction and is formed to be coupled to the side surface of the first plate or the second plate. Capacitor after Claim 1 wherein the condenser further includes a mounting unit that secures the condensation area and the subcooling area that are selected.

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